4 mole of pure liquid A `(P_(A)^(0)=80mm` of Hg) and 6 mole of pure liquid B `(P_(B)^(0)=100mm` of Hg) are mixed . The vapour pressure of the resulting solution is found to be 90 mm of Hg then

Two moles of pure liquid 'A' (P_(A)^(0)=80 mmof Hg) and 3 mole of pure liquid 'B' (P_(B)^(0)=120mm of Hg) are mixed . Assuming ideal behaviour

Two moles of liquid A(P_(A)^(0)=100 torr) and 3 moles of liquid B(P_(B)^(0)=150 torr) from a solution having vapour pressure of 120 torr. Based upon this observation one can conclude:

For the mixture of liquid "A" (P^(0)=40mm of Hg) and liquid "B" ( P^(0)=72mm of Hg), the vapour pressure is found to be 56mm of Hg. Assuming ideal behaviour of the solution

One mole of liquid A (vapour pressure =300 mm Hg ) and 2 moles of a liquid B (Vapour pressure =360 mm Hg) are mixed . The mole fraction of A in the vapour mixture if found to be 5//17 . Which of the following is correct ?

The vapour pressure of a mixure of 1 mole of liquid 'A' and 3 mole of liquid 'B' is 550 mm of Hg. When one mole of liquid 'B' is further added, the vapour pressure of the solution increases by 10 mm of Hg. The vapour pressure of pure liquid A and B are respectively in mm of Hg .

The vapour pressure of a pure liquid A is 40 mm of Hg at 310K. The vapour pressure of its liquid in a solution with liquid B is 32 mm of Hg. Mole fraction of A in the solution, if it obeys Raoult's law is :

The vapour pressure of water at 23^(@)C is 19.8 mm. 0.1 mole of glucose is dissolved in 178.2 g of water. What is the vapour pressure (in mm) of the resultant solution?

100g of liquid A(molar mass 140"g mol"^(-1) ) was dissolved in 1000g of liquid B(molar mass 180"g mol"^(-1) ). The vapour pressure of pure liquid B was found to be 500 torr. Calculate the vapour pressure of pure liquid A and its vapour pressure in the solution if the total vapour pressure of the solution is 475 torr.

The vapour pressure of pure water at 25^@C is 30 mm. The vapour pressure of 10% (W/W) glucose solution at 25^@C is